Valve device of injection molding device

ABSTRACT

A valve device is configured for obturating an opening of a channel defined in an injection molding device. The valve device includes a plug movably received in the channel, and a resilient member connected with the plug. The plug includes an obturating portion for obturating the opening of the channel. The resilient member is configured for driving the plug to its original position where the obturating portion obturates the opening, after the opening of the channel is opened.

Relevant subject matter is disclosed in the co-pending U.S. patent applications (application Ser. No. 11/956,345, and entitled “INJECTION MOLDING DEVICE;” application Ser. No. 11/956,347, and entitled “METHOD FOR ELONGATING FOIL;” application Ser. No. 11/956,348, and entitled “METHOD FOR MANUFACTURING A FOIL DECORATED MOLDING;” application Ser. No. 11/956,350, and entitled “INJECTION MOLDING DEVICE”), which are filed on the same date Dec. 14, 2007.

BACKGROUND

1. Field of the Invention

The present invention relates to valve devices, and particularly to a valve device of an injection molding device for manufacturing a foil decorated molding.

2. Description of Related Art

Conventionally, various kinds of methods for manufacturing a foil decorated molding, which is molded by an injection molding process and has a transfer layer removed from a substrate foil of a transfer foil and placed on the surface of the molding after the transfer foil is inserted into cavities in an injection mold, have been known in the art. Since the use of the method requires an alignment of the transfer foil along a cavity-forming face of the mold, the transfer foil is preheated before the injection molding process so as to be easily aligned along the cavity-forming face of the mold where the cavity-forming face thereof is greatly recessed or projected from a parting face of the mold.

A traditional injection molding method includes transferring a heater between the male mold and the female mold to heat the foil before matching the molds, and removing the heater after the foil is heated. However, because of the need for the heater and the space it occupies, cost and volume of the injection mold is increased. A new method is used for elongating the foil between the male and female mold by exhausting air from a cavity via the female mold and pressurizing the foil by inputting thermal medium to cause the foil to cling to an inner surface of the cavity of the female mold. However, in this method, the thermal medium cannot be controlled.

What is needed is to provide a valve device for controlling supply of a thermal medium to an injection molding device.

SUMMARY

In one embodiment, a valve device is configured for obturating an opening of a channel defined in an injection molding device. The valve device includes a plug movably received in the channel, and a resilient member connected to the plug. The plug includes an obturating portion for obturating the opening of the channel. The resilient member is configured for driving the plug to its original position where the obturating portion obturates the opening, after the opening of the channel is opened.

Other advantages and novel features of the present invention will become more apparent from the following detailed description of an embodiment when taken in conjunction with the accompanying drawings, in which:

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross-sectional view of an injection molding device having a valve device in accordance with an embodiment of the present invention, together with a foil, the injection molding device including a male mold and a female mold;

FIG. 2 is a cross-sectional view of the female mold, similar to FIG. 1;

FIGS. 3 and 4 are enlarged, partially cutaway views of the male mold of FIG. 1, showing two using states respectively;

FIG. 5 is a cross-sectional view of the female mold of FIG. 1, but showing the foil extending into the cavity of the female mold;

FIG. 6 is similar to FIG. 1, but showing the foil extending along an inner surface of the cavity of the female mold and the male and female molds matched together;

FIG. 7 is similar to FIG. 6, but showing a state after injection; and

FIGS. 8 and 9 are enlarged, partially cutaway views of the male mold in accordance with another embodiment of the present invention, showing two using states respectively.

DETAILED DESCRIPTION

Referring to FIG. 1, an injection molding device in accordance with an embodiment of the present invention includes a transport 10 for transporting a foil 100, a mold including a male mold 20 and a female mold 30, a plurality of pressing members 40, and a thermal medium source 90.

The male mold 20 has a projecting part 21 protruding toward the female mold 30. A plurality of air discharging holes 23 is defined in the male mold 20 around the projecting part 21 and extending from a side, facing the female mold 30, of the male mold 20 to an opposite side of the male mold 20. A pressure release valve 80 is connected to each air discharging hole 23. The pressure release valve 80 is adjustable according to need during molding. A plurality of receiving slots 25 is defined in the male mold 20 in vicinity of edges of the male mold 20. A plurality of hermetic rings 27 is received in the corresponding receiving slots 25.

Referring also to FIG. 2, the female mold 30 defines a cavity 31 therein. The cavity 31 includes a bottom surface A2, a first side surface A1 extending from an edge of the bottom surface A2, and a second side surface A3 extending from an opposite edge of the bottom surface A2 to a surface that faces the male mold 20, with an opening formed on the corresponding surface of the female mold 30. A length of the opening of the cavity 31 is L. A plurality of air discharging holes 32 is defined in the male mold 20 and extending from a side, facing the male mold 20, of the female mold 30 to an opposite side of the female mold 30. At least one of the air discharging holes 32 extends from the bottom surface A2 of the cavity 31 to the corresponding side of the female mold 30 opposite to the male mold 20. Each air discharging hole 32 is connected to a vacuum-pump at the side of the female mold 30 opposite to the male mold 20. A plurality of hermetic rings 33 is attached to the female mold 30 adjacent to an edge of the female mold 30.

Referring also to FIGS. 3 and 4, the male mold 20 defines a plurality of channels 29 therein extending from a side, facing the female mold 30, of the projecting part 21 to a side of the male mold 20 opposite to the female mold 30. Each channel 29 includes a bell-mouthed recessed portion 291 defined in the projecting part 21 facing the female mold 30, of the projecting part 21, a conduit 295 defined in the male mold 20 communicating with a small end of the recessed portion 291, and an L-shaped slender duct 296 with one end communicating with the conduit 295 and the other end passing through the surface opposite to the female mold 30, of the male mold 20. A block 298 protrudes in from one end opposite to the recessed portion 291, of the conduit 295. One end of a pipe 91 is connected to the end opposite to the female mold 30, of each slender duct 296, and the other end of the pipe 91 is connected to the thermal medium source 90. A through hole is defined in the block 298.

A valve device is arranged in each channel 29. In this embodiment, the valve device includes a plug 70 attached in each channel 29. The plug 70 includes a taper-shaped obturating portion 71 for obturating the recessed portion 291 of the channel 29, and a pole 73 extending from a small end of the obturating portion 71. The pole 73 extends through the through hole of the block 298. A fastening member 75 is fixed to a distal end of the pole 73. A resilient member 79, such as a spring, fits about the pole 73 and is resiliently located between the block 298 and the fastening member 75.

The thermal medium source 90 has thermal medium contained therein, such as thermal liquid or high-pressure gas. In this embodiment, the thermal medium is thermal high-pressure gas. The thermal medium is capable of being heated by an electric heater or an infrared ray heater (IR heater).

The transport 10 includes two transporting rollers 13 and two guiding rollers 15 positioned at two opposite ends of the mold respectively, for transporting the foil 100 into the mold. The foil 100 includes a base layer, and a printed layer attached to the base layer and having printed decorations.

Referring also to FIGS. 5 and 6, the foil 100 is transported into the mold and between the male and female mold 20, 30. The male and female mold 20, 30 are with the pressing members 40 locked together to form a molding space among the inner surface of the cavity 31 of the female mold 30, the projecting portion 21 of the male mold 20, and parts around the projecting portion 21. The pressing members 40 are received in the corresponding receiving slots 25, and press the corresponding hermetic rings 27, 33 to airproof the molding space. The molding space is separated into a first airproof space adjacent to the female mold 30 and a second airproof space adjacent to the male mold 20 by the foil 100. A vacuum is connected to the air discharging holes 32 of the female mold 30 to vacuumize the first airproof space, thus the foil 100 is sucked toward the first airproof space. The pressure release valve 80 is shut, and the value of the pressure release valve 80 is predetermined according to the molding condition. The thermal medium source 90 inputs heated gas to the channels 29 via the pipes 91. The plugs 70 are driven by the heated gas to move toward the female mold 30, therefore the channels 29 open. The heated gas is blown into the second airproof space to press and shape the foil 100 to cling to the inner surface of the cavity 31 of the female mold 30. The foil 100 is intenerated by the heated gas to cling to the inner surface of the cavity 31 easily.

Referring also to FIG. 7, molten resin is injected through an injection opening defined in the male mold 20 into the molding space. The molten resin presses the plugs 70 into the corresponding channels 29 against resistance of the corresponding resilient members 79. The heated gas in the second airproof space is released via the air discharging holes 23 of the male mold 20 when the pressure in the molding space is greater than the predetermined value of the pressure release valve 80. The molten resin is cooled to form a mold body. The mold is opened, with the male mold 20 being separated from the female mold 30. The base layer of the foil 100 is released from the mold body. Thus, the printed layer of the foil 100 is attached to a surface of the mold body.

In this embodiment, the injection molding device is used for elongating the foil 100 between the male and female mold 20, 30 by exhausting air from the cavity 31 via the air discharge holes 32 of the female mold 30 and pressurizing the foil 100 via the heated gas. For example, a length of the first side surface A1 is a1, a length of the second side surface A2 is a2, and a length of the bottom surface A3 is a3, when the first, second, and bottom surface A1, A2, A3 of the cavity 31 and the length L accord with an expression a1+a2+a3>=(1+20%)*L, the foil 100 is capable of being elongated for suiting the cavity 31 of the female mold 30.

Referring also to FIGS. 8 and 9, in another embodiment, the valve device includes a plug 70 a attached in each channel 29. The plug 70 a includes a taper-shaped obturating portion 71 a for obturating the recessed portion 291 of the channel 29, and a pole 73 a extending from a small end of the obturating portion 71 a. A hook 74 a is formed on one end of the pole 73 a away from the obturating portion 71 a. A resilient member 79 a is arranged between the hook 74 a and one end of the channel 29 away from the recessed portion 291. Two slender ducts 296 a are defined in the male mold 20 each with one end communicating with the end of the channel 29 away from the recessed portion 291 and the other end passing through the surface opposite to the female mold 30, of the male mold 20. The end opposite to the female mold 30, of each slender duct 296 a, is connected to the thermal medium source 90 via a pipe 91.

It is to be understood, however, that even though numerous characteristics and advantages of the present invention have been set forth in the foregoing description, together with details of the structure and function of the invention, the disclosure is illustrative only, and changes may be made in detail, especially in matters of shape, size, and arrangement of parts within the principles of the invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed. 

1. A valve device configured for obturating an opening of a channel defined in an injection molding device, comprising: a plug movably received in the channel, the plug comprising an obturating portion for obturating the opening of the channel; and a resilient member connected with the plug to drive the plug to its original position where the obturating portion obturates the opening, after the opening of the channel is opened; wherein the channel is connected to a thermal medium source, thermal medium from the thermal medium source is capable of driving the plug to open the channel; wherein the thermal medium is gas, an air discharging hole is defined in the mold for releasing the gas from the mold; and wherein the gas is heated by an electric heater or an infrared ray heater.
 2. The valve device as claimed in claim 1, wherein the opening of the channel is a bell-mouthed recessed portion, the obturating portion is taper-shaped corresponding to the opening of the channel.
 3. The valve device as claimed in claim 2, wherein the plug further comprises a pole extending from a small end of the obturating portion, one end of the resilient member is connected to the pole of the plug.
 4. The valve device as claimed in claim 3, wherein the other end of the resilient member is connected to one end of the channel opposite to the opening.
 5. The valve device as claimed in claim 2, wherein the plug further comprises a pole extending from a small end of the obturating portion, a block protrudes into the channel from one end opposite to the recessed portion, a through hole is defined in the block, the pole extends through the through hole of the block, a fastening member is fixed to a distal end of the pole, the resilient member fits about the pole and is resiliently located between the block and the fastening member.
 6. The valve device as claimed in claim 1, wherein the resilient member is a spring.
 7. The valve device as claimed in claim 3, wherein the channel comprises a conduit for communicating with a small end of the recessed portion, a slender duct with one end communicating with the conduit and the other end connected to the thermal medium source. 